Rajagopal B S, Lespinat P A, Fauque G, LeGall J, Berlier Y M
Section d'Enzymologie et Biochimie Bactérienne, CEN Cadarache, Saint Paul Lez Durance, France.
Appl Environ Microbiol. 1989 Sep;55(9):2123-9. doi: 10.1128/aem.55.9.2123-2129.1989.
The activities of pure and mixed cultures of Desulfovibrio vulgaris and Methanosarcina barkeri in the exponential growth phase were monitored by measuring changes in dissolved-gas concentration by membrane-inlet mass spectrometry. M. barkeri grown under H2-CO2 or methanol produced limited amounts of methane and practically no hydrogen from either substrate. The addition of CO resulted in a transient H2 production concomitant with CO consumption. Hydrogen was then taken up, and CH4 production increased. All these events were suppressed by KCN, which inhibited carbon monoxide dehydrogenase activity. Therefore, with both substrates, H2 appeared to be an intermediate in CO reduction to CH4. The cells grown on H2-CO2 consumed 4 mol of CO and produced 1 mol of CH4. Methanol-grown cells reduced CH3OH with H2 resulting from carbon monoxide dehydrogenase activity, and the ratio was then 1 mol of CH4 to 1 mol of CO. Only 12CH4 and no 13CH4 was obtained from 13CO, indicating that CO could not be the direct precursor of CH4. In mixed cultures of D. vulgaris and M. barkeri on lactate, an initial burst of H2 was observed, followed by a lower level of production, whereas methane synthesis was linear with time. Addition of CO to the mixed culture also resulted in transient extra H2 production but had no inhibitory effect upon CH4 formation, even when the sulfate reducer was D. vulgaris Hildenborough, whose periplasmic iron hydrogenase is very sensitive to CO. The hydrogen transfer is therefore probably mediated by a less CO-sensitive nickel-iron hydrogenase from either of both species.
通过膜进样质谱法测量溶解气体浓度的变化,监测了处于指数生长期的普通脱硫弧菌(Desulfovibrio vulgaris)和巴氏甲烷八叠球菌(Methanosarcina barkeri)纯培养物和混合培养物的活性。在H₂-CO₂或甲醇条件下生长的巴氏甲烷八叠球菌产生的甲烷量有限,且两种底物几乎都不产生氢气。添加CO会导致伴随CO消耗出现短暂的H₂产生。然后氢气被吸收,CH₄产量增加。所有这些事件都被KCN抑制,KCN抑制了一氧化碳脱氢酶的活性。因此,对于这两种底物,H₂似乎是CO还原为CH₄的中间产物。在H₂-CO₂条件下生长的细胞消耗4摩尔CO并产生1摩尔CH₄。以甲醇为生长底物的细胞利用一氧化碳脱氢酶活性产生的H₂还原CH₃OH,其比例为1摩尔CH₄比1摩尔CO。从¹³CO中仅获得¹²CH₄,未获得¹³CH₄,这表明CO不可能是CH₄的直接前体。在普通脱硫弧菌和巴氏甲烷八叠球菌以乳酸为底物的混合培养物中,观察到最初有一阵H₂的快速产生,随后产量降低,而甲烷合成随时间呈线性。向混合培养物中添加CO也会导致短暂的额外H₂产生,但对CH₄形成没有抑制作用,即使硫酸盐还原菌是非常敏感的希登伯勒普通脱硫弧菌(Desulfovibrio vulgaris Hildenborough),其周质铁氢化酶对CO也很敏感。因此,氢转移可能是由这两个物种中对CO不太敏感的镍铁氢化酶介导的。
